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Reprinted from Energy Progress, March. 1987
Design &Operation of a SelectiveSweetening Plant Using MDEA
Douglas H. MacKenzie and Francis Chiraka Prambil
Propak Systems Ltd., Airdrie, Alberta, Canada
Christina A. Daniels
Bryan Research & Engineering, Inc., Bryan, Texas
and
Jerry A. Bullin
Texas A&M University, Chemical Engineering Department College Station, Texas
Operating data were collected from the Signalta gas sweetening plant.The plant has had an interesting variety of
feed gas and operating conditions. The design and operation of he facility forC02 slippage are discussed.
INTRODUCTION
Th e Signalta Resources Forestburg Gas Plant was constructed during the winter of 1983 and placed on stream inApril of 1984. A design outlet gas specification of 1/4 grainH2Sil00 scf was requested to ensure meeting the contractcommitment of 1 grain/100 sc£ Th e design gas flow-ratewas 30 MMSCFD containi ng 0.5% H2S and 3% C02 at 415psia and 70°F.
Th e overall plant is configured as shown in Figure 1. Inle t separation facilities are followed by a feed gas heater.The gas stream then flows through a filter separator followed by the amine contactor. Another filter separator is
Figure 1. Block flow diagram for Forestburg Facility.
Energy Progress {Vol. 7, No. 1}
used as a sweet gas scrubber. After sweetening, the gas is
routed to a de w point control refrigeration unit. Finally, asingle stage of compression is required to boost the gas to
1200 psig maximum pipeline pressure.The sweetening chemical selected for the Forestburg
Plant was methyldiethanolamine (MDEA). This was
chosen due to its capability to remove H2 S and leave aportion of the C 02 in the residue gas. At the time of plant
commissioning it was one of the first operating MDEA fa-
cilities in Western Canada.Th e inlet gas·comes from 20 wells and is located in vari
ous pipelines up to 6" diameter with a total length of morethan 50 miles. Some of the wells produce as much as 2%H2S and occasionally some oil and asphaltene. The actualfeed stream reaching the plant normally contains 0.2 to0.4% H2S. Due to demand the flow rate has varied from 6
to 27 MMSCFD.Several tests of the plant were undertaken to detennine
the effects of changes in feed point on the contactor. This
information can be used to improve th e methods and assumptions used in the design of MDEA sweetening systems. Considerable interest is expressed by production
companies in the adjustability of C02 slippage that can be
obtained using MDEA. This opportunity is also used to
describe th e initial calculation procedures used to de-
velop an MDEA design.
PROCESS CHEMISTRY
Th e methyldiethanolamine (MDEA) process as used fornatural gas treating utilizes the selectivity of the chemical
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for H 2S in preference to C0 2 in a nonequilibrium situa
tion. Several sources of published material are available
describing the various reactions that may take place [1-6].The most significant observation fi·om a plant design per
spective is relatively simple. H 2 S chemically reacts with
MDEA almost instantaneously by proton transfer as is the
case with other commonly used amines.
H 2S + R2 NCH3 R2NHCH 4+ + HS -
Since MDEA is a tertia1y amine and does not have a hydrogen atom attached to the nitrogen atom, th e C02 reaction can only occur after th e C02 has formed bicarbonate
with water.
C0 2 + H20 HC03 + H+
It is th e formation of the bicarbonate which is generally
considered to be the slow reaction which limits th e C0 2
reaction to less than equilibrium values at short contact
times. The bicarbonate then undertakes an acid-base reaction with th e amine to yield an overall C0 2 reaction:
C0 2 + H 20 + H2 NC H3 H2 NHCH 4+ + HC03 -
Because of th e slow intermediate step required for th e
C0 2 and water it may be assumed that H 2S reaction with
MDEA is gas phase limited while th e C02 reaction is liquid phase limited [2]. It is obvious that to utilize MDEA
effectively in selective situations it is necessary to keepth e liquid phase contact time for th e reaction to a mini
mu m so that less C0 2 will be absorbed by the amine solution. Several mechanical design considerations must be
taken into account in proper absorber vessel design to en
sure that this will occur. Th e mechanical design require
ments have an effect on the process operation. Therefore,
it is necessary to properly allow reasonable first order estimates of th e mechanical influence on the process.
A computerized approach to the process design calcula
tions is a necessity in order to optimize th e design in anyreasonable time frame. Th e program used for the design
of the Signalta MDEA process was TSWEET from B1yanResearch & Engineering of Bryan, Texas. This program
does rigorous tray by tray calculations for th e contactor
an d stripper columns by th e Ishii-Otto method and contains a kinetic model to simulate th e effects of contact
time and th e MDEA selectivity. A modified Kent an d
Eisenberg equilibrium model is used to calculate the
vapor pressures of I-I2 S and C0 2 above the amine solu
tions. This program also contains th e ability to simulate
multiple feed points to th e absorber, which is one method
of control over the selectivity.
PRELIMINARY DESIGN CONSIDERATIONS
Several preliminary considerations should be examined
for each sweetening application. These include:
Circulation Rote
The ratio of C0 2 to H2S in the feed gas is of considera
ble importance in th e selection of MDEA as the sweeten
in g agent. The more C0 2 in relation to H 2S, the more attractive economically it will appear to remove only the
H2S. The original C02 to H2S ratio for the Forestburg plant
was 6:1 which was th e initial indication that MDEA was
worth considering. In addition, preliminary simulations
indicated that l/4 grain/100 SCF specification with
slightly less than 2% C0 2 in th e outlet gas was readily
achievable.
When initially designing an MDEA facility, a first estimate of th e circulation rate is required. A good approxima
tion is to calculate the amine rate required to remove allthe H 2S an d half of th e COz.
32 March, 1987
where
MM = gas flow MMSCFD
H2S = mol % of H2S to be removed
C02 = mol % of C02 to be removed
MWT = mole WT of MDEA = 119.9ML = mol loading, moles acid gas/mole
WT = amine solution weight percent circulated
Using th e design feed gas analysis for th e Forestburg
Plant from Table 1 as an example case, this is calculated asf()llows:
0.206 X 0.30 X (0.5 + 1.5) X 119.9GPM = - - - - - - - - - - - ; , ~ - - - : : c ; ; - - - - - ' - - - - - -
x
Thus, a preliminary circulation rate of 100 USGPM is selected. It is worth noting that the 0.3 mol loading was selected du e to the relatively low 415 psi operating pressure
of the Forestburg contactor. At higher pressures a mole
loading of0.4 to 0.5 would be a more representative initialestimate.
Troy Residence Time
The next step is to detennine the residence time in the
contactor. Because multiple feed points or parallel feeds
an d drawofis are often used for selective applications, it isnecessary to calculate this value on a stage by stage basisfor use in kinetic modeling. Th e exact tower and tray geometry is not known at th e start of th e design. The most
straightforward procedure is to initially assume two seconds residence time on the trays which receive full amine
flow. I f multiple feed points are used, the residence time
up th e column can be calculated by the inverse ratio of the
amine flow rates. Thus, no initial determination of th e
contactor diameter is required.
Designers who require a closer approximation of the
residence time must estimate the contactor diameter by
calculating the bubbling area and downcomer area [7, 8]as shown in Figure 2. The required active bubbling area
on a tray is primarily dependent on gas flow and secondar-
PERIPHERYWASTAGE
ACTIVE BUBBL_ING
AREA
OUTLET DISENGAGING
ZONE
hw
DOWNCOMER TO--+-
NEXT TRAY
Figure 2. Typical contoctor troy arrangement.
OUTLETWEIR
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ily on liquid flo"v rate. Th e required bubbling area can be
calculated by neglecting the liquid effect and using
Souder's and Brown's correlation [7]:
where
K(PI. - pc) 0.5
PG0,5
K 0.25 for valve trays, 0.20 fiJr bubble cap
traysUa 1 = allowable velocity of gas through bub
bling area, ft./sec.Pl. = density of the amine solution, lb./cu. ft.
PG = density of the gas at tray conditions, lb./cu.ft.
The downcomer area can be calculated from the liquid
flow rate assuming a downflow velocity of0.25 ft./sec. The
bubbling area plus two downcomers plus 15% for liquid
distribution zone and wastage are used as th e total tower
cross sectional area. Using the data fi·om Table l .
(64.4 - 1.41 )0
•5
Ual = 0.25 (1.41
)0 ·5 = 1.67 ft./sec.
Actual Volumetric Flow of Gas = ll ft3sec.
llBubbling Area = 1.
67= 6.6 sq. ft.
Area of Down comer =
100 GPM
0.25 ft./sec x (7.48 gallffl x 60 sec/min)
Total Required Tower Area =
(6.6 + .9 + .9) 1.15 = 9.66 ft. 2
This results in a tower I.D. of 42 inches
= 0.9 sq. ft.
Th e next step in determining the residence time on anactual tray is to calculate the depth of liquid on the tray.Th e assumption that the weir length is 0.7 times the tower
diameter is normally satisfactory for initial calculations.
The height of liquid over the weir is calculated using the
Francis straight weir relation [7].
l1ow = .48 (GPM/L)0·67
where L = weir length in inches
For the design case;
l1ow = .48 (100/(.7 x 42))0·67 = 1.1 inches
Th e standard weir height used by most tray manufacturersis 2.0 inches for a total from depth of 3.1 inches at the trayoutlet. Th e hydraulic gradient across the tray can also be
calculated. However, the error incurred by ignoring it at
this point is relatively minor.Th e so-called clear liquid residence time can now be
calculated.
Clear Liquid Residence Time =
Bubbling Area* Froth Depth- - - - - , ; ; - ; - ' = - - : - . - ~ - - ; c . : - - c - - - = - - - - * Froth GravityLiquid Flow Rate
Design Case:
6.6 ft. 2 * (3.1112) ft * 0.3CLRT = 100 GPM/(7.48 x 60) = 2·3 sees.
Th e product of the froth depth and hoth gravity, yields the
depth of the clear liquid on the tray. These factors must be
used since the fluid flowing across th e bubbling area isfroth oflow density due to the contained gas bubbles. Th e
2.3 second valve is quite close to the 2.0 second residence
time recommendation at th e beginning of this section. I fthe designer had used the 2.0 second estimate, the con
tactor size could be generated by the computer program
TABLE l. DESIGN & TEST DATA FO H SiGNALTA PLANT
Test A 85/12/16 Test B 86/02/27 Test C 86/02/27
Acid Acid Acid
Gas Stream Design Inlet G. Outlet Inlet G. Outlet Inlet G. Outlet--- - - - - - - - - - - - -C 0 2 Mole% 3.00 2.99 66.59 2.05 3.08 74.72 1.95 3.02 70.68 2.13H 2S Mole% .50 .43** 29.33 2.8ppm .31 20.29 .6-1.5 ppm .31 23.46 3.2-3.7 ppm
Flow Hate, MMSCFD 30.00 22.0 .32* 20.8 14.09 .21 12.98 14.16 .19 13.22Fuel Gas, MMSCFD By Difference .88 By Difference JJO By Difference .75Contractor:Gas In Temp, °F 70 59 60 60Gas Out Temp, °F 125 85 86 86.5L. Amine In Temp. 110 74 79 77.H. Amine Out Temp. 106 80 77 83Gas In Press, PSIA 428 432 393 393Avg. Gas #/ffl 1.41Amine Hate, GPM 100 72 70 70%to Tray 1 100 36 39 ll%to Tray 7 64 61 24
%to Tray 13 0 0 65Heboiler:Steam, lb/gal 1.2 1.5 1.55 1.55Press, PSIA 27.7 22 23 23AmineWt.% .50 36.2 32.4 32.25Stripper:
Feed Temp, °F 220 204 205 2040/H Cond. Temp. 120 88 87 93Hesidence Time:
Seconds
Tray 1-6 2.3 6.7 6.5 20.3Tray 7-12 2.3 2.9 2.9 7.1Tray 13-20 2.3 2.9 2.9 2.9
*Calculated by COz Balance** Calculated from Acid Gas Composition
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and the Francis weir equation [7] used to refine th e resi-dence time calculations.
Equilibrium Stages
The number of actual trays pe r theoretical stage is al-ways a point of discussion amongst equipment designers.
The situation is made more complex when entering th e
realm of nonequilibrium contact, where one of the compo-
nents is achieving only a certain percentage of equilib-
rium. A significant amount of research work has been done
an d there is more to be done in this area. Rather than bela-
bor the topic with a discussion of point efficiencies,
Murphree tray efficiencies and so on, a value of three ac-tual trays pe r theoretical stage gives realistic comparisons
between calculated an d actual results. A test of this
simplification is th e prediction of temperature profiles forabsorbers. Prior information published by Daviet, et a!.
[3] shows reasonable correlation between calculated an d
actual temperature profiles using the three actual trays
pe r stage approach.
Contactor Feed Points
The primary method of adjusting th e MDEA system
perf(mnance with regard to H 2S removal and C 02 slippage
is th e location an d quantity of amine delivered to different
feed points on th e contactor. In general, if the amine is to-tally supplied to only th e bottom few trays, the C 0 2 slip-
page will be quite high, possibly over 80%. Unf(H"tunately,this may also result in inadequate contact to achieve H 2Sspecification. The H 2S requirement can be achieved by
flowing a lesser amount of amine into a higher feed point
in th e tower. Some care must be taken with regard to feed
temperature and C 02 absorption heat of reaction. It is pos-
sible to create a temperature profile that will not improve
the absorption of H 2S clue to the elevated temperature and
C0 2 content of th e amine. Fortunately, this type of prob-
lem becomes apparent when th e calculations are rigor-
ously performed by computer. A reasonable level of
acljustability is provided by using three feed points. Sour
gas entering the Forestburg Plant contacts al l the amine on
th e bottom eight trays followed by a lower amine rate for
th e next six trays an d a final section of six trays at th e top ofth e contactor. Thus the amine feed points are on trays 1, 7ancl13 by process numbering convention. Diflerent feed
points could be selected based on the three actual trays
pe r theoretical stage rule an d calculations showing a pro-
cess benefit for th e change. Some applications will show
that 20 trays are not required, however it is very difficult
to convince an experienced amine plant purchaser of this,probably with past bitter experience as justification.
Stripping Rates
Amine plants have been designed for many years using
a rule of thumb of on e lb . of steam pe r gallon of amine cir-culated. The final requirements for stripping steam rate
must be determine! from th e rigorous computer calcula-tions. The stripping rate required is highly variable de-
pending on C 0 2/H 2S ratio an d may be as low as .8 to meet
a 1 grain/100 SC F H 2S specification an d as high as 1.5 to
meet l/ 4 grain/100 SC F H 2S specification. In general,
MDEA is easier to strip than other amines an d an operat-
in g rate of less than on e lb. steam/gallon will meet l/4
grain requirements. The ..design of th e stripper and
reboiler is conventional with respect to other amine sys-tem designs In the stripper, the trays have been found tobe more effrcient an d two actual trays pe r theoretical stage
should be tlsed. Packed towers are often used in stripping
applications an d an HETP of three feet is a conservative
value.
34 March, 1987
Design Optimization
The previous sections have outlined some basic as-sumptions an d methods of calculating first trials for th e
various design parameters. The design is then finalized by
providing the data to th e computer program for rigorous
calculation. When th e initial simulation results ar e ob-
tained they can be inspected and some of th e parameters
modified accordingly. For example, the stripping rate can
be reduced if H 2S content of th e outlet gas is significantlybelow l/4 grain pe r 100 SCF. Th e circulation rate can be
reduced to improve th e C 0 2 slippage. Residence times on
th e trays can be changed within the limits of contactor di-
ameter by a factor of about-50
to+
100 percent by se-lecting alternate weir heights. Changing th e quantity of
amine supplied to different feed points will show changes
in C0 2 slippage an d H2S sweetness. More H2S an d C0 2 are
removed from th e gas stream by increasing amine flowrates to more contact stages. I t should be noticed that it isnecessary to revise the contact times for each new amine
flowrate tested. This process of making slight alterations
to th e calculations is a valuable exercise for the designer
to perform so that critical limitatiom in th e final design
can be avoided. Selection of a process design which has
some flexibility will simplify th e selection of th e mechani-
cal equipment.
MECHANICAL EQUIPMENT
The selection of heat exchange and mechanical equip-
ment is often specific to a given plant process design
however some discussion of th e equipment used at the
Forestburg Plant is of some interest.
Leon Rich Exchanger
A plate/plate exchanger was used as th e lean/rich amine
,exchanger. This type of exchanger offers large s u r f ~ w e areas an d high transfer rates in a small volume. The de -
signer should be careful to allow for acid gas breakout on
the rich amine side of th e exchanger. This f[wtor is impor-
tant for both pressure drop and heat exchange considera-
tions. Th e pressure drop through th e lean side should be
kept below two psi to prevent pumping problems associa-
ted with reducing the lean amine below its vapor pressureat th e exchanger inlet nozzle. On the other hand it is ad-
visable to keep velocities high enough that th e exchanger
does not collect dirt. A single pass configuration on both
sides of this exchanger is advisable. The plates should be
316 SS, EPDM gaskets ar e recommended. A few years
ago, gasket leaks were the plague of plate/plate exchan-
gers. In general, this situation has been corrected. It is stillnecessary to have a spare set of gaskets readily available.
Booster Pumps
The common practice of placing the booster pumps
downstream of the lean/rich exchanger was not followed
in th e Forestburg degjgn, Sufficient NPSH was available
to allow these pumps to operate properly with the hot lean
amine directly from the reboiler. This was done in an at-Tempt to overcome the problem mentioned in th e previ-
ous paragraph. It also allowed the use of higher pressure
drop in th e plate exchanger and subsequent reduction in
size of that unit. The us e of high temperature seals an d
seal cooling were required, however. Although there have
been no problems with the selected arrangement, th e
more common practice is probably less expensive an d less
prone to design oversights which might cause pump cavi-tation. It is interesting to note that some amine plants have
no booster pumps on th e basis that sufficient NPSH isavailable for th e charge pumps without using a booster.
Ve1y often these designs ultimately have cavitation prob-
lems. The reason for this is th e presence of hydrocarbons
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in the amine which can reduce the NPSH available to half
of what would be expected from the amine solution vapor
pressure calculations.
Filtration
A full flow amine filter was incorporated into the
Forestburg Amine Plant. A 5% flow charcoal filter was alsoinstalled in the amine stream. Directly ahead of the amine
contactor in the gas stream a large filter separator removes
any particulate or liquid mists that might be present after
inlet separation. Even with all of the above filters an d adouble system wash before start-up, the Forestburg Plant
encountered foaming problems for th e first several weeksafter start-up. As this problem has almost entirely disap
peared without any mechanical modification, i t is pre
sumed that well completion fluids or oil entrainment were
the culprits. An asphaltene dispersant of unknown chemi
ca l composition injected at some of the wellheads seems
to have helped eliminate this problem as well. Th e use of
antifoam agents in the plant has been reduced to nil.
Air Coolers
The overhead condenser an d the lean amine cooler
were mounted in a common unit. Air recirculation and
tw o speed fan motors were also used to prevent freezing
problems at low ambient conditions. This is also the rea
son that a 50% M DEA solution was used in the originaldesign.
Charge Pumps
The highest maintenance items on the amine plant are
generally the charge pumps. Th e Forestburg Plant operat
ing pressure was sufficiently low that high speed centrifugal pumps could be economically used to pump the amine
solution up to contactor pressure. This type of pump ishighly recommended from a maintenance viewpoint. Mostof the inherent problems with the more commonly used
plunger pumps in amine service are a result of the packing
glands filtering iron sulfides ou t of the amine solution.
Build-up of these particles results in abrasion of the plun
gers and frequent replacement. Th e drawback of the cen
trifugal pump is its relatively low pumping efficiencywhich increases the horsepower consumption by a factorof approximately two. At high operating pressures the
plunger pumps are still the best choice du e to the high
comparative cost of multistage centrifugal pumps. The acceleration head requirements an d possible use of pulsa
tion dampening should not be overlooked when using
plunger pumps.
DISCUSSION OF PLANT TEST
Th e design considerations and methods previously discussed were used to design an MDEA ftlcility for th e
Signalta Forestburg Plant. Th e design information as de
tennined by final computer simulation is shown in th e first
column of Table 1. Th e process flow diagram for theamine process is shown in Figure 3.
Inlet, residue and acid gas samples were analyzed by
gas chromatograph. During test A, discrepancies were
found between the inlet H2S measurements and the acid
gas flow rates. Investigation into this problem uncovered
acid gas metering errors and variance between chromato
graph and Tutweiler H2S measurements. Therefore, it wasnecessary to calculate the acid gas rate based on the C02
concentration (a relatively large number) an d then back
calculate the inlet H 2S from the acid gas flow rate. This
corresponded with Gastec sample tube readings taken
during th e test. For the subsequent B an d C tests, H 2S.readings were taken by gas chromatograph, Tutweiler ap-
Energy Progress (Vol. 7, No. 1)
SOUFI: GAS
CONTACTOR
figure 3. Process flow diagram for Forestburg Sweetening Plant.
paratus and Gastec indicator tubes. Due to variations in
the different methods, the low and high readings were discarded and the remaining readings were averaged to show
the results in Table 1.
As with most operating facilities of this type, th e finaloperating conditions are never quite th e same as were estimated in th e original design. As can be seen from the
Test Data columns of Table 1, the plant operating pres
sures, temperatures and flow rates were quite different
from the original design.This type of disparity in th e design and test conditions
is probably the best test of the simulation program used todesign the plant. Table 2 shows that th e TSWEET pro
gram results conformed very closely to the test data when
actual operating conditions are simulated. Th e primmy effect for investigation was the influence of feed point and
contact time on the C02 slippage and H 2S sweetness. Thus
the tests were conducted using a high stripping rate tominimize the eflects of changes in lean amine loadings. It
is important to vary as few parameters as possible to ob
tain meaningful data. The simulation re,sults proved to be
very accurate within 5% for the C 02 slippage an d were
conservative for the H 2S calculations. I t is difficult toquantify the results concerning the H2S content in th e outle t
gas asth e
H2Smonitor at the site sampled the residue
gas every few seconds and variations of 1 ppm were no t
unusual between consecutive readings. We were pleased
that the prediction was slightly conservative.
CONCLUSION
Th e use of basic design parameters outlined earlier in
this paper allows the designer of an MDEA plant to ap-
TABLE 2. COMPAIUSON OF TEST DATA & SIMULATION HESULTS
Test A
C 0 2 ou tH2S ou t
C 02 mass balance
H 2S mass balance
Test BC 0 2 ou t
H 2S ou t
C 0 2 mass balance
H2S mass balance
Test CC 02 ou t
H2S ou t
C 0 2 mass balance
H2S mass balance
Test Predicted by TSWEET
2.05%2.8 ppm
*
1.95%.6-1.5 ppm
-1.5%
-2.5%
2.13%3.2-3.7 pp m
+1.0%+1.5%
2.14%3.2 ppm
1.92%1.94 ppm
2.01%4.5ppm
*Test A meter errors required C02 and H2S he used to calculate acid gas Oowrate.
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proximate the required circulation rates and heat loads.Subsequent use of a computerized simulation model,
which accounts for kinetic effects and performs rigorous
equilibrium calculations enables a large degree of refinement in the final design. Th e capability of modifying several parameters allows the designer to identify potential
limitations in the overall scheme and avoid deficiencies inthe final plant equipment selection.
ACKNOWLEDGMENTS
The authors appreciate the efforts of the following
individuals and companies for their persistence in allowing us to collect the plant operating data. Thanks toDon Widynowski of Widy Engineering Ltd., George
Hilderman of Core Laboratories Ltd., Ernie Dhenin of
Team 2 Operators Ltd., and Signalta Resources Ltd.
LITERATURE CITED
l . Savage, D. W., and E. W. Funk, "Selective Absorption of H2San d C 0
2into Aqueous Solutions of Methyldiethanolamine,"
36
Doug MacKenzie is Vice President of Engineering
at Propak Systems Ltd. office in Calgary, Alberta.
He has been design engineer of several gas processing plants including mechanical refrigeration,glycol dehydration, mole seive, and amine sweet
ening systems. He has 13 years experience as proj
ect engineer, process engineer and chief engineer.MacKenzie holds a B.Sc. in Mechanical Engineer
ing from the University of Calgary, is a member of
ASME and NACE, and a registered professional
engineer in th e province of Alberta, Canada.
Francis Chiraka-Parambil is a Senior Process Engineer at Propak Systems Ltd., office in Calgary.He has been involved with th e process design of
several natural gas plants and petro chemical
1plants. He has 17 years of experience as process
and project engineer, and holds a B.Sc. degree inChemical Engineering from University of Kerala,1India and an M.Sc. in Chemical Engineering fromOklahoma State University. He is a member of
A.I.Ch.E. and a registered professional engineer in
the province of Alberta, Canada.
March, 1987
paper presented at AIChE meeting, Houstin, Texas, April 5-9,
1981.2. Danckwerts, P. V., "Gas Liquid Reactions," McGraw Hill,
New York, 1970.
3. Daviet, G. R., R. Sundermann, S. T. Donnelly, J. A. Bullin,"Dome's North Caroline Plant Conversion to MDEA" Proceedings of Gas Processors Association Convention, New Or
leans, LA, p. 69 (March, 1984).
4. Ammons, H. L., an d D. M. Sitton, "Operation Data From aCommercial MDEA Gas Treater," paper presented at th e GasConditioning Conference, Norman, Oklahoma, March 2-4,
1981.5. Pennwalt Chemicals, "Methyldiethanolamine for Gas Sweet
ening," publication S-282.6. Jou, F. Y., D. Lal, A. E. Mather, and F. D. Otto, "Solubility of
Acid Gases in Methyldiethanolamine Solutions" paper pre
sented at Canadian Gas Processors Association meeting,
Calgary, March 12, 1981.
7. Perry & Chilton, "Chemical Engineers Handbook," Chapter
18, 5t h Ed.rion, McGraw Hill, New York (1973).
8. Smith, B. D., "Design of Equilibrium Stage Processes,"
McGraw Hill, New York, 1963.
Christina A. Daniels is a technical service engi
neer for Bryan Research and Engineering, Inc. lo
cated in Bryan, Texas. Sh e has been involved inthe process design and optimization of several
amine sweetening and Claus sulfur plants.
Christina was previously a Hesearch Engineer forDOW Chemical Company and contributed to th e
development of several adhesive polymers. She
holds a B.S. in Chemical Engineering from Texas
A&M University.
Jerry A. Bullin has a Ph D in Chemical Engineer
ing and is a registered Professional Engineer. He
is currently an Associate Professor in the Chemical
Engineering Department at Texas A&M Univer
sity. He has been working in th e simulation anddesign of gas processing facilities since 1972. He
has also worked for Jefferson Chemical Co. an d
Black, Sivalls and Bryson, Inc.
Energy Progress (Vol. 7, No. 1)